Abstract: An electronic isolation device is formed on a monolithic substrate and includes a plurality of passive isolation components. The isolation components are formed in three metal levels. The first metal level is separated from the monolithic substrate by an inorganic PMD layer. The second metal level is separated from the first metal level by a layer of silicon dioxide. The third metal level is separated from the second metal level by at least 20 microns of polyimide or PBO. The isolation components include bondpads on the third metal level for connections to other devices. A dielectric layer is formed over the third metal level, exposing the bondpads. The isolation device contains no transistors.

Abstract: An integrated circuit includes isolation capacitors which include a silicon dioxide dielectric layer and a polymer dielectric layer over the layer of silicon dioxide. The silicon dioxide dielectric layer and the polymer dielectric layer extend across the integrated circuit. Top plates of the isolation capacitors have bond pads for wire bonds or bump bonds. Bottom plates of the isolation capacitors are connected to components of the integrated circuit. Other bond pads are connected to components in the integrated circuit through vias through the silicon dioxide dielectric layer and the polymer dielectric layer.

Abstract: An electronic isolation device is formed on a monolithic substrate and includes a plurality of passive isolation components. The isolation components are formed in three metal levels. The first metal level is separated from the monolithic substrate by an inorganic PMD layer. The second metal level is separated from the first metal level by a layer of silicon dioxide. The third metal level is separated from the second metal level by at least 20 microns of polyimide or PBO. The isolation components include bondpads on the third metal level for connections to other devices. A dielectric layer is formed over the third metal level, exposing the bondpads. The isolation device contains no transistors.

Abstract: An integrated circuit includes isolation capacitors which include a silicon dioxide dielectric layer and a polymer dielectric layer over the layer of silicon dioxide. The silicon dioxide dielectric layer and the polymer dielectric layer extend across the integrated circuit. Top plates of the isolation capacitors have bond pads for wire bonds or bump bonds. Bottom plates of the isolation capacitors are connected to components of the integrated circuit. Other bond pads are connected to components in the integrated circuit through vias through the silicon dioxide dielectric layer and the polymer dielectric layer.

Abstract: An integrated circuit includes isolation capacitors which include a silicon dioxide dielectric layer and a polymer dielectric layer over the layer of silicon dioxide. The silicon dioxide dielectric layer and the polymer dielectric layer extend across the integrated circuit. Top plates of the isolation capacitors have bond pads for wire bonds or bump bonds. Bottom plates of the isolation capacitors are connected to components of the integrated circuit. Other bond pads are connected to components in the integrated circuit through vias through the silicon dioxide dielectric layer and the polymer dielectric layer.

Abstract: An apparatus for performing earth borehole operations comprising a base or substructure, a mast mounted on the base, a top drive mounted on the mast for longitudinal movement therealong, the top drive having an opening therethrough and a coiled tubing injector mounted on the mast above the top drive such that coiled tubing from the tubing injector can pass through the opening in the top drive, the apparatus being operable to selectively use the top drive to engage and manipulate a component used in borehole operations while the coiled tubing injector is substantially inoperative and selectively operable to use the coiled tubing injector to inject coiled tubing into an earth borehole while the top drive is substantially inoperative or alternatively using the coiled tubing injector to inject coiled tubing into a tubular string being manipulated by the top drive.

Abstract: A TSV-MEMS packaging process is provided. The process includes forming TSVs in the front side of the product wafer, and attaching a first carrier to the front side of the product wafer, subsequent to forming TSVs. The process further includes thinning the back side of the product wafer to expose TSV tips, detaching the first carrier from the front side of the product wafer, and transferring the thinned wafer to a second carrier with back side adhered to the second wafer carrier. Semiconductor components are added to the front side of the product wafer, followed by forming a hermetic cavity over the added semiconductor components, and detaching the second carrier from the back side of the product wafer. Wafer level processing continues after detaching the second carrier.

Abstract: An apparatus for performing earth borehole operations comprising a base or substructure, a mast mounted on the base, a top drive mounted on the mast for longitudinal movement therealong, the top drive having an opening therethrough and a coiled tubing injector mounted on the mast above the top drive such that coiled tubing from the tubing injector can pass through the opening in the top drive, the apparatus being operable to selectively use the top drive to engage and manipulate a component used in borehole operations while the coiled tubing injector is substantially inoperative and selectively operable to use the coiled tubing injector to inject coiled tubing into an earth borehole while the top drive is substantially inoperative or alternatively using the coiled tubing injector to inject coiled tubing into a tubular string being manipulated by the top drive.

Abstract: An apparatus for performing earth borehole operations comprising a base or substructure, a mast mounted on the base, a top drive mounted on the mast for longitudinal movement therealong, the top drive having an opening therethrough and a coiled tubing injector mounted on the mast above the top drive such that coiled tubing from the tubing injector can pass through the opening in the top drive, the apparatus being operable to selectively use the top drive to engage and manipulate a component used in borehole operations while the coiled tubing injector is substantially inoperative and selectively operable to use the coiled tubing injector to inject coiled tubing into an earth borehole while the top drive is substantially inoperative or alternatively using the coiled tubing injector to inject coiled tubing into a tubular string being manipulated by the top drive.

Abstract: There is disclosed a method of applying stress to a channel region underneath a gate of a field-effect-transistor, which includes the gate, a source region, and a drain region. The method includes steps of embedding stressors in the source and drain regions of the FET; forming a stress liner covering the gate and the source and drain regions; removing a portion of the stress liner, the portion of the stress liner being located on top of the gate of the FET; removing at least a substantial portion of the gate of a first gate material and thus creating an opening therein; and filling the opening with a second gate material.

Abstract: An apparatus for conducting earth borehole operations, comprising a base, a mast mounted on the base, and an integrated unit comprising a top drive and a coil tubing injector carried by the mast for longitudinal movement therealong. The top drive has an opening therethrough whereby coil tubing from the injector can pass through the top drive. There is a guide for coil tubing, the guide being selectively releasably connected to the coil tubing injector and mounted on the mast and selectively movable between a first position wherein coil tubing from the guide can be stabbed into the injector and a second position wherein coil tubing from the guide is out of alignment with the coil tubing injector.

Abstract: A TSV-MEMS packaging process is provided. The process includes forming TSVs in the front side of the product wafer, and attaching a first carrier to the front side of the product wafer, subsequent to forming TSVs. The process further includes thinning the back side of the product wafer to expose TSV tips, detaching the first carrier from the front side of the product wafer, and transferring the thinned wafer to a second carrier with back side adhered to the second wafer carrier. Semiconductor components are added to the front side of the product wafer, followed by forming a hermetic cavity over the added semiconductor components, and detaching the second carrier from the back side of the product wafer. Wafer level processing continues after detaching the second carrier.

Abstract: A semiconductor device is provided wherein at least one offset spacer is reduced and a non-conformal stress liner is thereafter deposited. By depositing the non-conformal stress liner in accordance with the present invention in close stress proximity to the FET, the carrier mobility and the performance of said device is significantly enhanced. The present invention is her directed to a method of fabricating said semiconductor device.

Abstract: Silicon on insulator devices having the body-tied-to-source are described. In an embodiment, a semiconductor device comprises: a gate conductor spaced above a semiconductor layer by a gate dielectric; dielectric spacers disposed laterally adjacent to sidewalls of the gate conductor; source and drain junctions laterally spaced apart by a body region in the semiconductor layer; and a conductive implant region comprising metallic species disposed in a bottom region of the semiconductor layer for electrically connecting the source junction to the body region, wherein a drain-side of the implant region is spaced apart from the body region and a source-side of the implant region contacts the body region.

Abstract: An apparatus for conducting earth borehole operations, the apparatus having a base, a mast mounted on the base, and an integrated top drive/CT injector unit carried by the mast for longitudinal movement therealong.

Abstract: There is disclosed a method of applying stress to a channel region underneath a gate of a field-effect-transistor, which includes the gate, a source region, and a drain region. The method includes steps of embedding stressors in the source and drain regions of the FET; forming a stress liner covering the gate and the source and drain regions; removing a portion of the stress liner, the portion of the stress liner being located on top of the gate of the FET; removing at least a substantial portion of the gate of a first gate material and thus creating an opening therein; and filling the opening with a second gate material.

Abstract: Methods of fabricating silicon on insulator devices having the body-tied-to-source are described. In an embodiment, a method of forming a transistor device comprises: providing a semiconductor topography comprising a gate conductor spaced above a semiconductor layer by a gate dielectric, dielectric sidewall spacers adjacent to sidewalls of the gate conductor, and source and drain junctions laterally spaced apart by a body region in the semiconductor layer; and implanting metallic species in a bottom region of the semiconductor layer to form a conductive implant region to electrically connect the source junction to the body region.

Abstract: A semiconductor device is provided wherein at least one offset spacer is reduced and a non-conformal stress liner is thereafter deposited. By depositing the non-conformal stress liner in accordance with the present invention in close stress proximity to the FET, the carrier mobility and the performance of said device is significantly enhanced. The present invention is her directed to a method of fabricating said semiconductor device.

Abstract: Embodiments of the present invention provide a method of forming a conductive stud contacting a semiconductor device. The method includes forming a protective layer covering the semiconductor device; selectively etching an opening down through the protective layer reaching a contact area of the semiconductor device, the opening being away from a protected area of the semiconductor device; and filling the opening with a conductive material to form the conductive stud. One embodiment may further include forming a dielectric liner directly on top of the semiconductor device, and forming the protective layer on top of the dielectric liner. Embodiments of the present invention also provide a semiconductor device made thereof.

Abstract: The present invention relates to a method of fabricating a semiconductor substrate that includes forming at least first and second device regions, wherein the first device region includes a first recess having interior surfaces oriented along a first set of equivalent crystal planes, and wherein the second device region includes a second recess having interior surfaces oriented along a second, different set of equivalent crystal planes. The semiconductor device structure formed using such a semiconductor substrate includes at least one n-channel field effect transistor (n-FET) formed at the first device region having a channel that extends along the interior surfaces of the first recess, and at least one p-channel field effect transistor (p-FET) formed at the second device region having a channel that extends along the interior surfaces of the second recess.